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Fused Silica Suspension Research at Caltech, Lately

Fused Silica Suspension Research at Caltech, Lately. Phil Willems LIGO/Caltech (lots of help from V. Sannibale, V. Mitrofanov, J. Weel) LSC Meeting, LLO March 20-23, 2002. Suspensions Apparatus. Automated fiber pulling lathe. Q-measurement rig.

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Fused Silica Suspension Research at Caltech, Lately

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  1. Fused Silica Suspension Research at Caltech, Lately Phil Willems LIGO/Caltech (lots of help from V. Sannibale, V. Mitrofanov, J. Weel) LSC Meeting, LLO March 20-23, 2002

  2. Suspensions Apparatus Automated fiber pulling lathe Q-measurement rig

  3. Mode frequencies enable precise determination of fiber radius

  4. Whammy Sidebands  16.65Hz  This allows measurement of Young’s modulus (74.5GPa).

  5. Temperature Shift of Unloaded Mode Frequencies Yields (dE/dT)/E

  6. The Frequency Shift of the Violin Modes Yields the Dilution Factor In general, For this suspension,

  7. And the Agreement is Good • data • theory

  8. Obtain the Structural and Thermoelastic Losses from Unloaded Fiber Q’s Best fit:

  9. Free fiber frequencies are very consistent with inferred diameter But now E=73GPa compared to 74.5GPa for violin modes; good agreement with stress-strain law E=E0(1+5.75e).

  10. Put it all together to predict Q theory, with NTE theory, w/o NTE theory, w/o NTE and a=5.9x10-7/K data

  11. Conclusions • Suspension fiber dynamics can be precisely quantified • Very high Q’s possible • Q’s not up to NTE level (and in fact more consistent with LTE theory- yikes!), but this likely due to low-frequency excess loss like recoil damping • Work is ongoing

  12. Dumbbell-Shaped Suspension Fibers A new technique for low vertical bounce frequency and low thermal noise

  13. Low thermal noise Optimum fiber diameter Smaller diameter increases noise Low bounce frequency Smaller fiber diameter better The Apparent Tradeoff low bounce frequency optimum thermal noise

  14. The Ribbon Solution • Make the cross-section as small as needed to reduce bounce frequency • Set the ribbon thickness to increase dilution factor and push thermoelastic peak to higher frequency

  15. Pendulum/violin motion Dissipative bending motion concentrated near ends of fiber Loss not very sensitive to middle section of fiber Vertical bounce motion Dissipative stretching motion distributed along fiber in inverse proportion to cross section But Notice the Different Dynamics of the Two Types of Motion

  16. This Suggests an Obvious Solution • Make the fiber the optimum thickness for low damping at the top and bottom, and thinner in the middle for low vertical bounce frequency- • aDUMBBELLshape

  17. The Equations of Motion

  18. The Boundary Conditions

  19. The Boundary Conditions

  20. How the Boundary Conditions are Derived

  21. Thermal Noise Spectra: Baseline Ribbon vs. Dumbbell Fiber ribbon dumbbell fiber

  22. Influence of Welded Pins on Suspension Q • This program can easily model the welded pins on the ends of suspension fibers (extreme dumbbell) • Good approximation if pins are relatively long and thin • Used this analysis to confirm Mitrofanov and Tokmakov’s estimate of Q due to lossy pins

  23. Result of Simulation • Mitrofanov/Tokmakov estimate: • This is based upon estimate of force exerted on pin by fiber • Our result: this is substantially correct, although for thicker fibers the torque also plays a significant role

  24. The Big Result A reasonably good, reasonably short pin will not unduly influence Q or thermal noise

  25. Fused Silica Materials Properties Database • Many different sets of material parameters for fused silica are in use by the various LSC groups to design suspensions and predict thermal noise. • This leads to much confusion when comparing results between groups. • I became aware of this when analyzing violin mode data above. • We need a common set of values shared by the community to facilitate information transfer.

  26. Proposed Material Parameters IN CONSTRUCTION (I have lots of Syracuse data to digest)

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